Longitudinal Changes in Children’s Speech and Voice Physiology after Cochlear Implantation

Objectives The purposes of this investigation were 1) to describe speech/voice physiological characteristics of prelingually deafened children before and after cochlear implantation and determine whether they fall into a range that would be considered deviant, 2) to determine whether selected deviant articulatory and phonatory behaviors of children with cochlear implants persist despite long-term cochlear implant use and continued participation in aural rehabilitation services, and 3) to determine whether further development of deviant articulatory and phonatory behaviors occurs postimplantation. Design Seven prelingually deafened children who received cochlear implants after 5 yr of age were followed from shortly before implantation until 5 to 6 yr postimplantation. These children received their early education in a Total Communication environment and used the Nucleus 22-electrode cochlear implant. All of them initially used the MPEAK speech processing strategy, and five of them eventually upgraded to the SPEAK speech processing strategy. Speech/voice physiological measurements that were obtained periodically from the children included intraoral air pressure (Po), nasal and phonatory air flow, voice onset time (VOT), and fundamental frequency (Fo). Data from the deaf children were compared with a database from 56 children with normal hearing to determine when the deaf children exhibited “deviant” speech/voice behaviors. Speech/voice behaviors were considered “deviant” if they never occurred for children with normal hearing or were associated with z-scores that were outside the range of ±2.0. Results The deaf children showed a wide range of deviant speech and voice behaviors both pre- and post-cochlear implant. The most frequently occurring atypical behaviors were use of negative Po, high Po for [b, m], long and short VOT for [p], and high Fo. Some deviant behaviors improved post-cochlear implant. However, deviant behaviors often persisted for several years post-cochlear implant. There was considerable evidence of further development of deviant behaviors post-cochlear implant. All of the deaf children demonstrated deviancy on at least two of our measures at the last data collection interval (5 to 6 yr post-cochlear implant). Conclusions Children who received cochlear implants after 5 yr of age and who were educated in a Total Communication setting showed persistence and further development of deviant speech/voice behaviors for several years post-cochlear implant. Although our findings cannot be generalized to other populations of children with cochlear implants (i.e., those who were implanted earlier, those educated in auditory-oral programs), it seems wisest at the present time not to assume that children’s deviant speech/voice behaviors will remit spontaneously with continued cochlear implant use. Our data provide an important comparative database for future investigations of pediatric cochlear implant users who have had shorter periods of auditory deprivation and who have received cochlear implants with more current technological features. Longitudinal Changes in Children’s Speech and Voice Physiology after Cochlear Implantation

[1]  R Netsell,et al.  Aerodynamic and electroglottographic measures of normal voice production: intrasubject variability within and across sessions. , 1994, Journal of speech and hearing research.

[2]  P. Dagenais,et al.  Comparing tongue positioning by normal-hearing and hearing-impaired children during vowel production. , 1992, Journal of speech and hearing research.

[3]  J. W. Heller,et al.  Cochlear implant technology , 1996, Proceedings of 18th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[4]  M. B. Higgins,et al.  Use of Visual Feedback to Treat Negative Intraoral Air Pressures of Preschoolers With Cochlear Implants , 2000 .

[5]  B J Gantz,et al.  Cochlear implant use by prelingually deafened children: the influences of age at implant and length of device use. , 1997, Journal of speech, language, and hearing research : JSLHR.

[6]  V. Samar,et al.  Articulatory dimensions of hearing-impaired speakers' intelligibility: evidence from a time-related aerodynamic, acoustic, and electroglottographic study. , 1989, Journal of communication disorders.

[7]  R. Netsell,et al.  Developmental patterns of laryngeal and respiratory function for speech production. , 1994, Journal of voice : official journal of the Voice Foundation.

[8]  T J Hixon,et al.  Effect of lung volume on voice onset time (VOT). , 1993, Journal of speech and hearing research.

[9]  T J Hixon,et al.  Nasal air flow during normal speech production. , 1979, The Cleft palate journal.

[10]  Steven M. Barlow,et al.  Vocal tract aerodynamics during syllable productions: Normative data and theoretical implications , 1991 .

[11]  M. A. Carpenter,et al.  Speech sample effects on pressure and flow measures in children with normal or abnormal velopharyngeal function. , 1999, The Cleft palate-craniofacial journal : official publication of the American Cleft Palate-Craniofacial Association.

[12]  E. Yiu,et al.  Voice activity and participation profile: assessing the impact of voice disorders on daily activities. , 2001, Journal of speech, language, and hearing research : JSLHR.

[13]  P. Dagenais,et al.  Consonant lingual-palatal contacts produced by normal-hearing and hearing-impaired children. , 1991, Journal of speech and hearing research.

[14]  L. Leonard The nature of deviant articulation. , 1973, The Journal of speech and hearing disorders.

[15]  B E Smith,et al.  Pressure-flow measurements for selected oral and nasal sound segments produced by normal adults. , 1991, The Cleft palate-craniofacial journal : official publication of the American Cleft Palate-Craniofacial Association.

[16]  R. Mayo,et al.  Aerodynamic and temporal aspects of velopharyngeal function in normal speakers. , 1996, Journal of speech and hearing research.

[17]  D. Zajac Pressure-flow characteristics of /m/ and /p/ production in speakers without cleft palate: developmental findings. , 2000, The Cleft palate-craniofacial journal : official publication of the American Cleft Palate-Craniofacial Association.

[18]  D R Beukelman,et al.  Intraoral air pressure during the production of /p/ and /b/ by children, youths, and adults. , 1978, Journal of speech and hearing research.

[19]  I R Titze,et al.  On the relation between subglottal pressure and fundamental frequency in phonation. , 1989, The Journal of the Acoustical Society of America.

[20]  M. Svirsky,et al.  The Effects of Processor Strategy on the Speech Perception Performance of Pediatric Nucleus Multichannel Cochlear Implant Users , 1998, Ear and hearing.

[21]  M. J. Osberger,et al.  Speech Production Characteristics of the Hearing Impaired , 1982 .

[22]  R Netsell,et al.  Vowel-related differences in laryngeal articulatory and phonatory function. , 1998, Journal of speech, language, and hearing research : JSLHR.

[23]  Mario A. Svirsky,et al.  The Effect of Auditory Feedback on the Control of Oral‐Nasal Balance by Pediatric Cochlear Implant Users , 1998, Ear and hearing.

[24]  Philipos C. Loizou,et al.  Mimicking the human ear , 1998, IEEE Signal Process. Mag..

[26]  R. Daniloff,et al.  Selected aerodynamic characteristics of deaf individuals during various speech and nonspeech tasks. , 1982, Folia phoniatrica.

[27]  H Lane,et al.  Changes in speech breathing following cochlear implant in postlingually deafened adults. , 1991, Journal of speech and hearing research.

[28]  D. Kessler,et al.  The Clarion® Multi-Strategy™ Cochlear Implant , 1999, The Annals of otology, rhinology & laryngology. Supplement.

[29]  G Weismer,et al.  Oral airflow and air pressure during speech production: a comparative study of children, youths and adults. , 1985, Folia phoniatrica.

[30]  G. E. Peterson,et al.  Control Methods Used in a Study of the Vowels , 1951 .

[31]  J S Perkell,et al.  Effects of short-term auditory deprivation on speech production in adult cochlear implant users. , 1992, The Journal of the Acoustical Society of America.

[32]  D J Povel,et al.  Predicting voice quality of deaf speakers on the basis of glottal characteristics. , 1990, Journal of speech and hearing research.

[33]  C. Sapienza,et al.  Developmental changes in laryngeal and respiratory function with variations in sound pressure level. , 1997, Journal of speech, language, and hearing research : JSLHR.

[34]  M J Osberger,et al.  Speech recognition performance of pediatric Clarion patients. , 1997, The American journal of otology.

[35]  T. Hixon,et al.  A clinical method for estimating laryngeal airway resistance during vowel production. , 1981, The Journal of speech and hearing disorders.

[36]  J. Perkell,et al.  Objective assessment of vocal hyperfunction: an experimental framework and initial results. , 1989, Journal of speech and hearing research.

[37]  N. Young,et al.  Speech Perception of Young Children Using Nucleus 22-Channel or Clarion® Cochlear Implants , 1999, The Annals of otology, rhinology & laryngology. Supplement.

[38]  H Lane,et al.  Speech of cochlear implant patients: a longitudinal study of vowel production. , 1992, The Journal of the Acoustical Society of America.

[39]  C. Newman,et al.  The Voice Handicap Index (VHI)Development and Validation , 1997 .

[40]  Raymond D. Kent,et al.  Acoustic Analysis of Speech , 2009 .

[41]  M. Rothenberg,et al.  Monitoring vocal fold abduction through vocal fold contact area. , 1988, Journal of speech and hearing research.

[42]  A. Carney,et al.  Physiological assessment of speech and voice production of adults with hearing loss. , 1994, Journal of speech and hearing research.

[43]  A. Carney,et al.  Negative intraoral air pressures of deaf children with cochlear implants: physiology, phonology, and treatment. , 1996, Journal of speech and hearing research.